倍福宁传感器选型手册

Viatran Phone: 1‐716‐629‐38003829 Forest Parkway Fax: 1‐716‐693‐9162_______________White PaperGuide to Pressure Transducer SelectionMost applications for pressure transducers are relatively straightforward. Install the transducer according to manufacturer’s recommendations, and obtain an accurate reading from an exceptionally reliable device. But life does not always follow the straight and narrow path. The purpose of this article is to provide some guidelines for helping a transducer user detect atypical conditions and compensate for them through the proper selection and application of the transducer.Why Use a Transducer?Pressure transducers are used to generate an electrical output for a variety of uses that may include computerized data collection, process monitoring and control, or electronic transmission of a pressure reading to a remote display. Another reason for using transducers is their accuracy. Transducers provide accuracies ranging from 0.1 percent full scale, with a typical accuracy of 0.5 percent.The greater the accuracy required, the more expensive the pressure measuring device. But since product quality in many processes is directly related to how accurately the pressure is maintained, the expense of a more accurate device will quickly be justified.Dealing with Abnormal ConditionsOnce the need for a pressure transducer has been determined, it is prudent to determine if there might be some out of the ordinary conditions that could upset transducer performance. The balance of this article will identify some of these conditions and what can be done to compensate for them.Temperature DynamicsTwo sources of temperature variation can affect transducer performance-ambient conditions and the fluid medium itself. Ambient conditions include such things as abrupt changes in air temperature due to heating and cooling systems cycling on and off and the effects of radiant energy impinging on the transducer. Variations in the fluid temperature occur most often during start-up of a process as the fluid goes from room temperature to a higher operating temperature.Dynamic temperature problems may arise because pressure transducers are calibrated under static conditions of both pressure and temperature. Dynamic temperature effects in the field, therefore, may be superimposed on a steady pressure condition and cause an unstable reading. The easiest solution to this problem is to wait for the temperature to achieve a steady state before making a pressure reading.Viatran Phone: 1‐716‐629‐38003829 Forest Parkway Fax: 1‐716‐693‐9162If accurate pressure readings must be made during large ambient temperature transitions, then corrective measures must be taken. Shielding the transducer may ameliorate ambient temperature shifts; you can build a baffle around it or wrap it with Styrofoam or some other insulating material.One-way to compensate for temperature effects of the media is to buffer the transducer by placing it at the end of a short length of stainless steel or copper tubing. The tubing dissipates excess heat at a rate determined by the material, diameter, and length of the tubing. Charts are readily available to help determine the proper dimensions of the tubing. This tubing forms a constant and acceptable temperature link between the transducer and the main body of fluid media.Media CompatibilityMost transducer media contact surfaces are made from stainless steel, either 17-4PH (precipitation hardenable) or 15-5PH. These are excellent special-purpose materials providing corrosion resistance similar to 303 and 304 grades of stainless steel. These materials handle most fluid media very well. If you know from previous experience, however, that these materials are unacceptable, then inform your transducer supplier. It is very likely that other options are available.Mechanical Shock and VibrationExcessive mechanical shock and vibration could develop due to reciprocating engines, piston pumps, hydraulic cylinders, and cycling valves. Cables that are subjected to continuous flapping may eventually break, and pressure fittings might eventually work loose.Strain-gauge transducers typically hold up extremely well under shock and vibration, and field-testing by manufacturers has brought about continual improvement in this area. This does not mean, however, that all caution should be thrown to the wind. If a transducer is likely to be exposed to a great deal of shock and vibration, tie the cabling down and/or protect it with conduit. Also use a high-quality pressure fitting and make certain that the transducer has been properly tightened.Dynamic OverloadA dynamic overload is a transient pressure spike of a magnitude greater than normal operating pressure. Such overloads may be present due to complex system dynamics and are very hard to trace. They can be as much as 10 times greater than the system pressure the transducer was designed to measure.Viatran Phone: 1‐716‐629‐38003829 Forest Parkway Fax: 1‐716‐693‐9162Dynamic overloads can place unacceptable stress on the transducer diaphragm and could cause zero shifts and possible transducer damage. The nature of these adverse effects depends on the magnitude and duration of the over-load. Short duration overloads usually present fewer problems than long duration overloads, which can seriously diminish transducer performance.If a zero shift due to an overload is suspected, drop the pressure in the system to zero and check the transducer’s zero output. Usually, a high positive zero shift is an indication of a pressure overload. If pressure spikes are a persistent problem, you may need to buy a higher rated transducer or correct the system dynamics with surge tanks and/or snubbing devices such as quick opening bypass valves, spring-loaded ball valves, and sintered metal snubbers. Also, relocation of the transducer may diminish or eliminate the overload condition.One Dynisco customer who needed to measure a pressure typically at 100-psi had severe system transients to 750-psi and was damaging 100-psi transducers. Because the ambient and fluid temperatures were quite steady, the customer was able to buy a 500-psi transducer and operate it at one-fifth the signal. Using the higher range unit eliminated all transducer damage.Fortunately, most transducers do not have to worry about dynamic overload. If you don’t think you have a dynamic overload problem, then you probably don’t. If a problem does exist, your supplier will help you evaluate the options.Dynamic ResponseMost transducer users want to measure pressure in a steady state. They don’t want to know what is happening to the pressure as changes take place. However some users want to measure dynamic pressure changes in the system. For these users, it is very important that they tell their transducer supplier that this is what they want to do.The dynamic response of a system is a very complicated subject. This complexity is further compounded by the sometimes-misunderstood usage of such terms as frequency response, dynamic response, response to a step input, and rise time. These terms mean one thing when applied to the transducer and another when referring to the system. If dynamic measurements are required, it is wise to discuss the application with the manufacturer and seek his advice.In addition to entering into a dialogue with your supplier, here are a few additional guidelines for using transducers to measure dynamic pressure:Viatran Phone: 1‐716‐629‐38003829 Forest Parkway Fax: 1‐716‐693‐91621. Couple the transducer as near as possible to the measuring point2. Use a flush diaphragm transducer instead of a cavity type for better frequencyresponse.3. Avoid isolating the transducer with tubing or snubbers because system dynamicswill change.Handling and InstallationAs mentioned earlier, today’s pressure transducer is an exceptionally rugged device. Even so, it pays to exercise a little common sense during handling and installation. Here are a few easy-to follow tips:1. Be careful with the electrical termination. Damage to the electrical connector orcable could put the transducer out of service.2. Never poke the diaphragm of a low-capacity transducer with a pencil point orother stiff object.3. This could damage the diaphragm, which in turn would affect transducerperformance.4. Do tighten the transducer well, making certain there is no leakage at the pressureconnection.5. Make sure the pressure fitting is made of a compatible material. Combiningmaterials with different expansion characteristics (say a brass fitting and a steel transducer) could result in a leak.6. If the transducer has a zero and span adjustment, position it so the adjustmentcan be reached with a screwdriver.7. Upon installation of the transducer, check the entire system for proper wiring,integrity of connections, and proper grounding.ConclusionRemember, experience has shown that most problems are instrument-or-system related, not transducer related. Poor electrical connections and improper grounding could cause elusive intermittent problems. If the problem persists even after a thorough system check, it may be reasonable to suspect that the transducer is faulty.This article has addressed questions users most often ask about the selection and application of pressure transducers. If you have any of the problems mentioned here, then it might be wise to consult directly with your transducer supplier. Tell him what your application is and what you hope to achieve through pressure measurement. A little time spent up front talking with the supplier can identify and compensate for potentially expensive problems before they have a chance to materialize.Viatran Phone: 1‐716‐629‐38003829 Forest Parkway Fax: 1‐716‐693‐9162。

纳韦测试公司压力传感器选型手册微型探针，薄片，汽车，航空，钻井，高温，低温压力传感器目录标准型压力传感器微型探针压力传感器XCQ-062系列-超小型IS®压力传感器（-55℃到120℃） (2)XCS-062系列-超小型IS®压力传感器（-55℃到120℃） (3)XCL-072系列-超小型IS®压力传感器（-55℃到120℃） (4)XCQ-080系列,XCL-080系列-小型IS®压力传感器（-55℃到120℃） (5)XCQ-093系列,XCL-093系列-标准小型IS®压力传感器（-55℃到120℃） (6)XCS-093系列-高灵敏度小型IS®压力传感器（-55℃到120℃） (7)XCL-100系列-小型IS®压力传感器（-55℃到120℃） (8)XCQ-152系列,XCL-152系列-短壳体IS®压力传感器（-55℃到120℃） (9)小型螺纹压力传感器XT-140(M)系列,XTL-140(M)系列-超小型IS®压力传感器（-55℃到175℃） (10)XT-190(M)系列,XTL-190(M)系列-小型耐用IS®压力传感器（-55℃到175℃） (11)XCS-190(M)系列高阻抗-小型高灵敏度IS®压力传感器（-55℃到175℃） (12)XTM-190(M)系列-小型耐用IS®压力传感器（-55℃到175℃） (13)XTL-76A-190(M)系列-小型IS®压力传感器（-55℃到204℃） (14)XTL-76A-312(M)系列-小型IS®压力传感器（-55℃到204℃） (15)XTL-AC-190(M)系列-小型耐用IS®压力传感器（-55℃到175℃） (16)XT-375(M)系列,XTL-375(M)系列-小型耐用IS®压力传感器（-55℃到175℃） (17)HKM-375(M)系列,HKL-375(M)系列微型高压IS®压力传感器（-55℃到175℃） (18)高温压力传感器XCE-062系列-高温超小型IS®压力传感器（-55℃到273℃） (19)XCEL-072系列-高温小型IS®压力传感器（-55℃到273℃） (20)XCE-093系列,XCEL-093系列-高温小型IS®压力传感器（-55℃到273℃） (21)XCEL-100系列-高温小型IS®压力传感器（-55℃到273℃） (22)XCE-152系列,XCEL-152系列-高温短壳体IS®压力传感器（-55℃到273℃） (23)XTE-190(M)系列,XTEL-190(M)系列-小型耐用IS®高温压力传感器（-55℃到273℃） (24)XTME-190(M)系列-小型高温耐用IS®压力传感器（-55℃到235℃） (25)XTEH-7L-190(M)系列,高温IS®压力传感器（-55℃到343℃） (26)XTEH-10L-190(M)系列-超高温IS®压力传感器（-55℃到482℃） (27)XTEH-7LAC-190(M)系列-高温低G灵敏度IS®压力传感器（-55℃到400℃） (28)XTEH-10LAC-190(M)系列-超高温、低G灵敏度IS®压力传感器（-55℃到482℃） (29)HEM-375(M)系列,HEL-375(M)系列微型高温IS®压力传感器（-55℃到232℃） (30)微小扁平传感器LQ-47系列-微扁平型应力隔离表面安装IS®压力传感器（-55℃到120℃） (31)LQ-062系列,LE-062系列-微小扁平型IS®压力传感器（-55℃到120℃/235℃） (32)LL-072系列,LLHT-072系列-超小扁平IS®压力传感器（-55℃到120℃/235℃） (33)LQ-080系列,LE-080系列,LL-080系列,LLHT-080系列扁平型IS®压力传感器（-55℃到120℃/235℃） (34)LQ-125系列,LE-125系列,LL-125系列,LLHT-125系列扁平型IS®压力传感器（-55℃到120℃/235℃） (35)LLE-1-500系列-微型扁平放大输出压力传感器（-40℃到140℃） (36)LLE-1-500系列-微型扁平放大输出压力传感器（-40℃到140℃） (37)LLE-2DC-750系列-微型扁平放大输出压力传感器（-40℃到140℃） (38)钻井油田压力传感器HKM-198- 375系列,HKM-198- 375M系列-钻井用小型压力传感器（-55℃到200℃） (39)HKM-189- 375系列,HKM-189- 375M系列-钻井用小型压力传感器（-55℃到200℃） (40)IPT-6-750HT系列-钻井用IS®压力传感器（-40℃到175℃） (41)IPT-4N-750HT系列-钻井用IS®压力传感器（-40℃到175℃） (42)IPT-25-750系列-小型钻井IS®压力传感器（-40℃到175℃） (43)汽车压力传感器XTL-123B-190(M),XTL-123C-190(M)系列汽车耐用IS®压力传感器（-55℃到204℃） (44)XTL-HA123B-190(M)系列,XTL-HA123C-190(M)系列汽车耐用IS®压力传感器（-55℃到204℃） (45)XTL-163-190(M)系列-汽车耐用IS®压力传感器（-55℃到204℃） (46)HKL-AC-375（M）系列-汽车/发动机用IS®压力传感器（-20℃到140℃） (47)HKM-113-375（M）(制动系统), HKM-142-375 (M) (MAP系统）汽车IS®压力传感器（-55℃到204℃） (48)XTL-142B-190(M)系列,XTL-142C-190(M)系列汽车耐用IS®压力传感器（-55℃到204℃） (49)通用型压力传感器IPT-750系列,BM-750M系列-齐平膜IS®压力传感器（-55℃到120℃） (50)IPT-1100系列, IPTE-1100系列-5VDC输出IS®压力传感器（-55℃到120℃） (51)BM-1100系列, BME-1100系列-5VDC输出 IS®压力传感器（-55℃到120℃） (52)BMD-1100系列, BMDE-1100系列-5VDC输出IS®差压传感器（-55℃到120℃） (53)航空压力传感器APT-20-1000 (100mV 输出),APT-51-1000 差压(100mV 输出) （-55℃到155℃） (54)APTE-6-1000 (5V 输出),APTE-51-1000差压(5V输出)（-55℃到155℃） (54)APTE-DC-1100系列5VDC高精度数字补偿飞机适用IS®压力传感器（-55℃到175℃） (56)EPS-1000系列-电子压力开关（-55℃到125℃） (57)放大输出型压力传感器ETL-76A-190(M)系列5VDC输出IS®压力传感器（-55℃到190℃） (58)ETL-76M-190(M)系列5VDC输出IS®压力传感器（-40℃到140℃） (59)ETL-76M-312(M)系列5VDC输出IS®压力传感器（-40℃到140℃） (60)ETM-DC-375(M)系列,ETL-DC-375(M)系列-5VDC数字调节IS®压力传感器（-40℃到140℃） (61)ETM-375(M)系列,ETL-375(M)系列-5VDC输出IS®压力传感器（-55℃到120℃） (62)ETM-200-375(M)系列,ETL-200-375(M)系列小型4-20mA输出IS®压力传感器（-55℃到120℃） (63)ETQ-500系列-5VDC输出IS®压力传感器（-55℃到120℃） (64)ETQ-12-375（M）系列- 5VDC输出齐平膜IS®压力传感器（-55℃到120℃） (65)ETQ-13-375（M）系列4~20mA输出齐平膜IS®压力传感器（-55℃到120℃） (66)ETM-HT-375(M)系列,ETL-HT-375(M)系列-齐平膜5VDC输出IS®压力传感器（-55℃到120℃） (67)超低温压力传感器CT-190(M)系列小螺纹低温压力传感器（-195.5℃到175℃） (68)CT-375(M)系列小螺纹低温压力传感器（-195.5℃到175℃） (69)特殊压力传感器WCT-250系列-水/气冷凝IS®传感器（24℃到704℃） (70)WCT-312系列-水/气冷凝IS®传感器（24℃到704℃） (71)HKL-1T-375（M）系列-微型、带有温度IS®压力传感器（-55℃到175℃） (72)ETL-1T-375（M）系列-微型5VDC输出带有温度IS®压力传感器（-55℃到175℃） (73)微型螺纹和标准螺纹压力传感器安装手册 (74)微型探针压力传感器-工作温度-55℃到120℃XCQ-062系列-超小型IS ®压力传感器● 直径1/16英寸 ● 可提供任何标准的压力量程 ● 对风洞中的应用最理想 ● 优越的静态和动态性能 ● 牢固耐用1.7 3.5 7 17 35 70 Bar 压力范围25501002505001000 psi工作模式 绝压、表压、密封表压、差压 过载压力 2倍额定压力，校准值无变化破裂压力 3倍额定压力压力介质 所有非导电性、无腐蚀性的液体和气体额定激励电压 10VDC/AC 最大激励电压 15VDC/AC 输 入输入阻抗 1000Ω (最小) 输出阻抗1000Ω(额定值) 满量程输出（FSO ） 100mV (额定值) 零位不平衡 ±5mV (典型值) 综合非线性和迟滞 0.1%FS BFSL (典型值)迟滞 0.1% (典型值) 重复性0.1% (典型值) 分辨率无限小 固有频率(kHz) (典型值)400 500 650 900 1300 1600 垂直 3.0×10-4 1.5×10-4 1.0×10-4 5.0×10-5 3.0×10-5 2.0×10-5 加速度灵敏度%FS/g 横向6.0×10-53.0×10-52.0×10-51.0×10-56.0×10-64.0×10-6输 出 绝缘电阻 ≥100M Ω (在50VDC 时) 工作温度范围 -55℃到120(℃-65℉到250)℉补偿温度范围 25℃到80(80℃℉到180)℉，可以要求在工作范围内的任何100℉的范围热零点漂移 ±1% FS /100℉ (典型值) 热灵敏漂移 ±1% FS /100℉ (典型值)稳态加速度≤10 000g环境条件 线性振动 10-2000Hz 正弦波， ≤100g 电气连接 4根38AWG 导线，长30英寸 重量 0.2克 (额定值)，不包括组件和连接导线敏感原理 惠斯登电桥电介质绝缘硅叠硅 物理性能 备注此产品长度最小为2.54mm微型探针压力传感器-工作温度-55℃到120℃XCS-062系列-高灵敏度超小型IS ®压力传感器● 高灵敏度 ● 优越的信噪比 ● 静态和动态能力 ● 宽动态范围0.35 1.0 Bar 压力范围515 psi工作模式 绝压、表压、密封表压、差压 过载压力 2倍额定压力，校准值无变化破裂压力 3倍额定压力压力介质 所有非导电性、无腐蚀性的液体和气体额定激励电压 15VDC/AC 最大激励电压 20VDC/AC 输 入输入阻抗 1000Ω(最小) 输出阻抗1000Ω(额定值)满量程输出（FSO ） 125mV(额定值) 对于密封表压50mV(额定值)200mV(额定值)对于密封表压100mV(额定值)零位不平衡 ±5mV(典型值) 综合非线性和迟滞 0.25%FS BFSL(典型值)迟滞 0.1% (典型值) 重复性 0.1% (典型值) 分辨率无限小固有频率(kHz) (典型值) 300 300 垂直 2.0×10-3 7.0×10-4 加速度灵敏度%FS/g 横向4.0×10-42.0×10-5输 出绝缘电阻 ≥100M Ω (在50VDC 时) 工作温度范围 -55℃到120(℃-65℉到250)℉补偿温度范围 25℃到80(80℃℉到180)℉，可以要求在工作范围内的任何100℉的范围热零点漂移 ±1% FS /100℉ (典型值) 热灵敏漂移 ±1% FS /100℉ (典型值)稳态加速度≤10 000g环境条件 线性振动 10-2000Hz 正弦波， ≤100g 电气连接 4根38AWG 导线，长30英寸 重量 0.2克 (额定值)，不包括组件和连接导线敏感原理 惠斯登电桥电介质绝缘硅叠硅 物理性能 备注此产品长度最短为2.54mm微型探针压力传感器-工作温度-55℃到120℃XCL-072系列-小型IS ®压力传感器● 直径0.072英寸 ● 无引线专利技术 ● 优越的静态、动态响应能力 ● 理想的探针应用产品XCEL-072采用了Kulite 的无引线专利技术，使结构包装坚固耐用，适宜于与耙形探针或其它类似设备结合应用。

POSITION SENSORSSensata - BEI Sensors product offering includes acomprehensive range of output options that allowusers to integrate the product in all the most commonnetwork interfaces.Refer to the table below for the output optionassociated to each product seriesthe latest optical, magneticSIL3/Sensata - BEI Sensors is the preferred position sensors partner to leading companies around the globe.Sensors used in the oil and gas industry must withstand high temperature and pressure in potentially explosive locations and extreme shock and vibration,along with exposure to chemicals, dirt and moisture. Position sensors perform crucial functions in oil and gas applications and must operate reliably day in and day out to ensure an optimized yield. Sensata is well aware of these unique upstream, midstream and downstream requirements and has designed products that feature uncompromising quality and performance. Hard anodized housings, gross leak tests, extended temperature ranges and a variety of sealing options are available on numerous Sensata products. Sensata also offers one of the largest selection of hazardous area rated products, including UL Class I Division 1 and 2, and Class II Division 1 and 2, and ATEX Zone 1 and Zone 2 (See page 9). A variety of communication protocols including Profibus, CANopen and DeviceNet are also offered.to resist pressurized spray, condensation and dust. Sensata’s products are built tough to operate reliably in these severe conditions.Sensata’s products have stood the test of time, providing a high degree of reliability and performance, while withstanding the severe conditions posed by off-road and industrial vehicle applications. These demanding applications rely on precise position sensing and redundant safety for steering and wheel systems, steer-by-wire systems, gear sensing, pedal and throttle control, hand acceleration, valve and control logging, cabin controls and more. Whether exposed to dirt, extreme temperatures, or moisture, the rugged construction of Sensata products ensures their accurate and reliable operation day after day, year after year.Sensata has supplied high quality, rugged encoders to heavy motor manufacturers for decades. Heavy motors are found in all types of harsh industrial environments and require extremely rugged feedback devices.Sensata’s products have the proven reliability needed for successful operation in these environments. If a motor is needed for use in a hazardous area, simply select one of Sensata’s large catalog of UL and ATEX pre-certified products. They provide drop-in feedback solutions that are ready to operate in hazardous areas worldwide. Custom product adaptations are also available for seamless integration into any motor design. Sensata’s design engineers are always on hand to provide any amount of Cranes are critical pieces of equipment for a variety of industries around the world. The environments where they operate are almost as diverse as the materials they move. Whether it’s loading and unloading cargo in unforgiving seaports, or handling material on a factory floor, cranes require reliable feedback solutions to do their job properly and safely. BEI Sensors offers a variety of position sensors and a real-time wireless interface system, rugged enough for the toughest environmental conditions, while providing the position and speed feedback needed to move materials with precision and accuracy.Heavy MotorsCranesOff-Road Equipment for Construction & AgricultureOil & Gas|FUNCTIONAL SAFETY SPLITTERS|INCLINOMETERS OUTPUT TYPEFemale Support + Magnet (M9105/Kxx) Male Support + Magnet (M9105/M10-01) Front Support + Magnet (M9105/F26)Mounting/AdaptersSensata | BEI Sensors’ exhaustive experience and capabilities in design, engineering and manufacturing allow us to provide innovative adapted products and complete custom solutions to meet unique position sensor requirements. F or decades we have provided thousands of modifications to all our standard products. From customizations as simple as adding a connector or changing a shaft size to merging parts of two standard products, Sensata takes pride in its ability to adapt to any customer’s product needs.Other adaptations require more significant changes, such as the modification of a product’s size and shape so that it will fit into a particular package design. Complete customization, where the technology itself is adapted to meet a customer’s requirements, is also fully within Sensata’s capabilities. Our experienced engineering team works closely with customers to help specify their requirements, outline a design, develop prototypes and—after final customer approval—move the custom sensor into production.Sensata has the ability and willingness to make these types of modifications, ensuring that you will receive a position sensor configured to your specifications , allowing drop-in installation and simplifying production and assembly at your facility. If you are not finding exactly what you need in this catalog, just ask and we will be happy to create a customized solution with you.EXTENSIVE PRODUCT ADAPTABILITYABOUT USSensata Technologies is one of the world’s leading suppliers of sensing, electrical protection, control and power management Array solutions with operations and business centers in twelve countries. Sensata’s products improve safety, efficiency and comfort for millions of people every day in automotive, appliance, aircraft, industrial, military, heavy vehicle, heating, air-conditioning and ventilation, data, telecommunications, recreational vehicles and marine applications. F or more information please visit Sensata’s website09/2021Copyright © 2021 Sensata Technologies, Inc.CONTACT USAmericas+1 (800) 350 2727 – Option 1****************************Europe, Middle East & Africa+33 (3) 88 20 8080****************************Asia Pacific*************************.comChina +86 (21) 2306 1500Japan +81 (45) 277 7117Korea +82 (31) 601 2004India +91 (80) 67920890Rest of Asia +886 (2) 27602006 ext 2808。

PrecisionLine RCR-PETDual Technology Motion SensorInstallation InstructionsDescriptionPrecisionLine dual technology motion sensors combine range-controlled radar (RCR) technology with a passive infrared (PIR) system to increase false alarm immunity by allowing them to sense human-sized objects within a speci-fied range. Both the RCR and PIR systems must be triggered to set off an alarm.The sensor is designed to use a 12VDC power supply provided by a UL Listed control panel.FeaturesThe sensor provides the following features:•Pet Immune up to 80 lbs.•Selectable range up to 35 feet (10.7m) - Internal jumper allows radar range selection to optimize coverage.•LED indicator - A multi-color LED provides detector status.• Opaque Fresnel lens - Blocks visible light.PartsThe following parts are included with the sensor:• RCR-PET sensor•1 screw to join the case halves •2 factory-installed jumpersSelecting a Location for the SensorThe sensor can be mounted in a corner or on a flat wall. Use the following guidelines to determine the best location to install the sensor:•Mount the sensor so the expected movement of anintruder is within a 90-degree radius in front of the sensor.See Figure 2.•Mount the sensor on a stable surface 7 to 8 feet (2.1 to 2.4m) high.•DO NOT mount the sensor within 2 feet (0.6m) of metallic objects.•DO NOT place objects in front of the sensor that may prevent a clear line of sight.•Avoid locations that expose the sensor to possible false alarm sources such as:– Moving or vibrating objects (fans, pulleys, conveyor belts)– Electronic fields (electric motors, high voltage equipment)– Water spray or corrosive environments– Heat sources (heaters, radiators) in the field of view – Windows in the field of view– Strong air drafts on the sensor (fans, air conditioners)Figure 1. Sensor (exploded)Figure 2 - RCR and PIR Coverage Patterns7’ (2.1m)35’(10.7m)35’(10.7m)Top ViewSide ViewRadar PIRFigure 3. Sensor Base•When installing multiple sensors:– DO NOT mount sensors facing each other.– Mount them at least 20 feet (6.1m) apart.– Mounting sensors back to back is not recommended, but if an application requires such mounting, use the 9-foot (2.7m) range, mount at least 1foot (0.3m) apart, and walk test the installation to ensure proper operation.Installing the SensorAll wiring must conform to the National Electric Code (NEC)and/or local codes having jurisdiction.Important: DO NOT use this device for safety interlock applications.Use the following steps to install the sensor:1.Run the security system wiring to the sensor location.2.Lift off the front cover/electronic module. Remove the nameplate and loosen the screw if necessary. See Figure 1.CAUTIONY ou must be free of all static electricity before handling sensor circuit boards. Touch agrounded, bare metal surface before touching circuit boards or wear a grounding strap.3.If necessary, set the jumpers on the circuit board. See Setting the Jumpers .4.Remove the appropriate wiring and mounting knock-outs from the back cover. The sensor can be mounted on a flat wall or in a corner. See Figure 3.5.Pull the wires through the knockout holes and use the two screws provided to attach the base to the wall. Use screw anchors if necessary.6.Strip 1/4 inch (6.4 mm) of insulation from each wire.7.Run each wire through the strain relief and under the appropriate screw terminals on the base and tighten the screws. See Figure 3.8.Line up the tabs on the bottom of the cover/electronic module with the corresponding tabs on bottom of the base and snap the cover/electronic module firmly down onto the base.9.Tighten the screw and replace the nameplate. See Figure 1.10.Apply power. The LED should light green for approxi-mately 25 seconds and then go out.11.Walk test the coverage pattern as follows:– Walk throughout the intended coverage area.– V erify the sensor alarms. See Understanding the LED .Figure 4. Main Circuit BoardJ2 RangeUnderstanding the LEDThe multi-color LED located on the bottom of the sensor indicates the status of the unit as described in the following table.Maintaining the SensorWhen installed and used properly, the sensor provides years of service with minimal maintenance. You should walk test the sensor annually to ensure proper operation.SB01 Swivel Mount BracketFor ceiling-mount applications that require 90 degreecoverage, an optional ceiling-mount swivel bracket (SB01) is available. See Figure 5.Figure 5. SB01 Swivel-Mount BracketAfter 30 minutes the LED will only indicate an alarm condi-tion. Drop power to reset the walktest timer.Pet ImmunityWhen mounted properly, the RCR-PET sensor provides false alarm immunity to dogs and similar animals. The size and temperature of the animal, which is affected by the length of the animal’s coat, affects the immunity to false alarms. Dogs vary in body temperature by breed, a very warm-blooded dog with short hair will not be as immune to false alarms as a similar sized dog with long hair. Therefore, the acceptable short hair dog is limited to a smaller (lighter) weight dog. See the examples listed in the following table:Important: You need to set J2 as close to the intended coverage range as possible. Overshooting the coverage area may cause false alarms.J3 LED -ON = LED enabled (factory default)OFF = LED disabledSetting the JumpersThe sensor provides jumpers to select the detection range and LED operation. See Figure 4.J2 Range - Use the jumper to cover the center pin and the pin indicating the desired range. No jumper = 27 feet (8.2m) and under.35 feet (10.7m) and under 27 feet (8.2m) and under(Factory default)18 feet (5.5m)and under 9 feet (2.7m) and under9’(2.7m)9’(2.7m)18’(5.5m)18’(5.5m)35’(10.7m)35’(10.7m)27’(8.2m)27’(8.2m)9’(2.7m)9’(2.7m)18’(5.5m)18’(5.5m)35’(10.7m)35’(10.7m)27’(8.2m)27’(8.2m)SpecificationsInput voltage 8.5 to 18VDC (UL: 10 to 16VDC)Typical current 20mA Maximum current 27mA Electrical configuration Form ARelay rating 40VDC, 300mA max.,6W Load max.Detection range 35' (10.7m) x 90°Target velocity 0.5 ft/sec to 5 ft/sec Alarm duration 5 sec. ± 10%Mounting height 7' to 8' (2.1m to 2.4m)Operating temperature 32°F to 122°F (0°C to 50°C)Relative humidity 5 to 93% non-condensingDimensionsWidth 2.8" (71mm)Height 5.1" (130mm)Depth 2.3" (58mm)Weight 6 oz (170g)ColorWhite Field wiring size 12-24 AWG ListingsC-UL USFCC ComplianceThis device complies with Part 15 of the FCC rules.Operation is subject to the following two conditions:(1) This device may not cause harmful interference.(2) This device must accept any interference received,in-cluding interference that may cause undesired operatio n .FCC ID : CGGAA2Product Ordering1037946 Rev C 04/04Tech Support 800-648-7424FaxBack: GE Security12345 SW Leveton Drive Tualatin, OR 97062503-692-4052USA & Canada: 800-547-2556GE Securityg。

EE210传感器选型手册FeaturesApplicationsHumidity and T emperature Transmitter for Demanding Climate Control ApplicationsEE210Appropriate for USmounting requirements ?Knockout for ?” conduit fittingDisplaySelectable display layout ?Measurands freely selectableExternal mounting holes ?Mounting with closed cover ?Electronics protected against construction site pollution ?Easy and fast mountingBayonet ScrewsOpen/closed with a ? rotationCast Electronics ?Mechanical protection ?Condensation-resistantElectronics on the underside of the PCB ?Optimum protection against mechanical damage during installation E+E Humidity sensor HCT01 ?Long-term stabilityProtected RH sensor surface ?Protected solder padsTested according to automotive standard AEC-Q200The EE210 transmitter by E+E Elektronik meets the highest requirements in deman-ding climate control applications. Besides highly accurate measurement of relative hu-midity and temperature, EE210 calculates dew point temperature, absolute humidity and mixing ratio.EE210 is available as wall or duct mounted. The enclosureminimizes installation costs and provides outstanding protection against contamination and condensation Two of the measured and calculated values are available on the analogue voltage or current outputs, while up to three values can be shown simultaneously on the optional display.Excellent performance of EE210 in polluted, aggressive environment is ensured by the combination of completely protective encapsulated measurement electronics inside the sensing probe and the long-term stable HCT01 sensor with E+E proprietary coating.With an optional configuration kit the user can setup the output scaling and perform one or two point adjustment humidity and temperature for humidity and temperature.agriculturestables, incubators, hatchers ? green housesstorage rooms, cooling chambers ? indoor poolsSmooth cover surface ?No accumulation of dust in protruding edgesMeasured valuesRelative Humidity Sensor E+E Sensor HCT01-00D Analog output 0...100% RH 0-5 V -1 mA < I L < 1 mA 0-10 V -1 mA < I L < 1 mA 4-20 mA (two-wire) R L ≤ 500 Ohm Working range 0...100% RH Accuracy (incl. hysteresis, non-linearity and repeatability) -15...40°C(5...104°F) ≤90% RH ±(1.3 + 0.3%*mv) % RH -15...40°C (5...104°F) >90% RH ± 2.3% RH -40...60°C (0...140°F) ±(1.5 + 1.5%*mv) % RH TemperatureSensor Pt1000 (tolerance class B, DIN EN 60751) integrated in HCT01 Analog output 1) 0-5 V -1 mA < I L < 1 mA 0-10 V -1mA < I L < 1 mAGeneralPower supply for 0-5 V / 0-10 V 15 - 35V DC 2) or 24V AC ±20% for 4-20 mA10V + R L x 20 mA < V+ < 30V DC Current consumption (voltage output) with DC power supply typ. 5mAwith AC power supply typ. 13mA eff ConnectionScrew terminals, max. 1.5 mm 2Housing material Polycarbonate, UL94V-0 approved Protection class IP65Cable gland M16 x 1,5 Temperature ranges Operating temperature: -40...60°C (-40...140°F)Storage temperature: -40...60°C (-40...140°F)Technical dataDimensions (mm)1) Output scaling see Ordering Guide2)USA & Canada: class 2 supply required, max. supply voltage 30VConnection diagramEE210-HT6xPAxB-UwTx005MModel: Humidity+Temperature Transmitter Analog output: 4-20mAHousing: polycarbonate Type: wall mount Display: none Filter: membrane filter Output scaling 1: relative humidity Scaling 1: 0...100% RH Output scaling 2: temperature Scaling 2: 0...100°C Output: metricOrder exampleOrdering GuideAccessories- configuration adapter (incl. USB cable for PC) HA011050- cable for configuration adapter HA011062- power supply for EE210 V03 (optional)- configuration software: free of charge; download: /doc/1bb79ff4168884868662d639.html /EE210PCConfigurations kit for adjustment of humidity and temperature, for selecting physical quantities and for setting the output scaling, consisting of (for details see data sheet at /doc/1bb79ff4168884868662d639.html /configurations-kit):relative humidity0...100% RHwater vapour partial pressure 0...200mbar 0...3psimixing ratio0...425g/kg 0...2900gr/lb absolute humidity 0...150g/m30...60gr/ft3specific enthalpy0...400kJ/kg 0...200BTU/lb4) Available from June 20142) Factory Scaling3) For Tx, TD und TF;other scaling upon request1) Factory setup:The display shows the measurands selected for output 1 and output 2。

--您可信赖的传感技术专家！压力、液位、温度传感元件 Pressure、Liquid-level、Temperature Sensor & Transmitter选 型 手 册(　201２年版　)※压力传感器及变送器Pressure Sensor and Transmitter※液位测量变送器Liquid-level Measuring Transmitter※温度传感器及变送器Temperature Sensor and Transmitter宁 波 控 泰 电 气 有 限 公 司NINGBO CONTECH ELECTRIC CO,.LTD.公司简介宁波控泰电气有限公司是宁波宁兴国贸实业有限公司投资控股的集研发、制造、贸易于一体的高新技术企业。

公司以传感技术为核心专业从事压力传感器、温度传感器、高精度称重传感器、力传感器、称重计量控制系统、计算机测控系统、称重软件等的研发与制造。

公司有雄厚的资金后盾。

高、新、尖技术力量为核心，依托中科院、中国电子科技集团、航天科工等大型科研单位，技术力量雄厚，合作伙伴遍布全世界。

我们不仅与国内有实力的企业开展产业合作，更寻求与国际大型跨国公司强强联手，让我们的产品与服务昂首迈入国际化的水准。

产品出口东南亚、欧美市场。

在衡器、冶金、石化、环保、造纸、医疗、等领域拥有广泛的应用前景。

公司先后通过和取得了ISO9001-2008国际质量体系认证、CMC制造许可证、EX 防爆认证、TX特种设备认证。

拥有CAD与FEA技术研发中心和传感器实验室。

拥有一条现代化的传感器生产线，通过引进国外先进的技术工艺，结合先进的管理经念，制造品质一流的传感器。

控泰电气将在“互诚、互信、互利、互惠”的基础上为您提供“称心的售前服务、省心的售中服务、放心的售后服务”，共同创造和见证您我共同发展的辉煌历程！基于 MEMS技术的压力传感的优势Advantages of Pressure Sensor Based on the MEMS Technology领先的技术Leading Technology基于 MEMS（微机电）技术的压力传感器，它是建立在微米/纳米基础上，在单晶硅片上刻融制作惠斯登电桥（Wheatstone bridge）组成的硅应变计，具有输出灵敏度高，性能稳定，批量可靠性、重复性好等优点。

〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗
〖由于继续研究和生产的发展，深索公司保留在没有通知的情况下做修改的权力〗。

1a 1b1cA BC DE n g l i s hPEONIA Flush mounted control element deviceWARNINGRisk of death and fire!Dangerous currents flow through the body when coming into direct or indirect contact with live components. This can result in electric shock, burns or even death. Work improperly carried out on current-carrying parts can cause fires. Disconnect the mains power supply prior toinstallation and/or disassembly! Permit work on the 230V supply systemto be perform only by specialist staff./lowvoltage/directives▪ Please read the mounting instructions carefully and keep them for future use.▪Additional user information and detailed information for parameter setting is available at or by scanning the QR code.Intended useThe sensor unit (with integrated bus coupler) can be as-sign to an available switch actuator. The devices serve for switching processes.For detailed information about the range of functions see the technical reference manual (see QR code).ABB i-bus ®KNX SensorPEONIA Flush mounted control element, 2/4 gang with RTC, 3/6 gang with RTC, 5/10 gang with RTC.Product featuresPEONIA control element are integrate with room tempera-ture controller, TFT display (dynamic graphic), tempera-ture sensor and proximity sensor. Rocker are exchangea-ble with corresponding icon. LED are the top and bottom functioning as ambient lighting. Function as input sensor for controlling KNX actuators device.Technical dataAmbient temperature -5 °C ~ +45 °C ProtectionIP 20Cable connection 2 x 2 x 0.8，0.5 mm² – 2 x 1 mm² Bus subscribers => 12 mAPower supply24 VDC (via bus line) Auxiliary power supply24 VDCMountingThey may only be installed in dry interior rooms in flush mounted boxes. Observe the current valid regulations.1a. Screw and install mounting backet onto flush mounted box1b. Connect bus line onto KNX connector, connect aux power supply ontoaux connector (KNX connector color : Red and Black ; aux connector : Yellow and White)1c. Insert KNX connector and aux connector onto the back of ABB i-bus ®KNX sensor respectively1d. Insert ABB i-bus ®KNX sensor onto mounting bracket2. Install / replace of rocker[A] CommissioningVarious functions can be implement via the ETS commissioning software. The function of the push-button coupling unit is depend-ent on the parameters selected via the respective software applica-tion.■ Detailed information about commissioning and parameterization is avail-able in the technical reference manual (see QR code).■ Always use the latest firmware version. The latest download files for the firmware update are contained in the electronic catalogue(/knx). The update is carry out via the KNX bus. For a de-tailed description, see the technical reference manual (see QR code). [1] Programming button. Press the programming button, the bottom LED ambient light turns red indicating switchover to programming mode [2] Temperature sensor[3] Ambient LED (top and bottom)[B] OperationCommon control configuration [0] TFT display screen [1] Scroll up selection [2] Scroll down selection [3] Fan speed adjustment [4] Menu button, on/off [5] Light off [6] Light on[7] Dim light down/off [8] Dim light up/on [9] Blind close/down [10] Blind open/up [11] Reading scene [12] Party scene[13] Master off scene [14] Master on scene[5] ~[14] Button function can be change and configure to suit user preference via ETS commissioning software[C+D] Displays / messages [C] RTC function, operation [1] Fan speed[2] Operating state[3] Mode: comfort mode, Standby mode, frost/heat pro-tection mode[4] Subdisplay (time, PM2.5, CO ₂, Humility, VOC, Room temperature)[D] Display layout[5] Main display, (Real time/setpoint, °C/ °F) [6] SubdisplayIconsA Comfort modeB Standby modeC Dew point warningD Frost/Heat protection modeE Condensation warningF Menu button, on/offG ECO ModeH Fan speed autoI Switchover heating/cooling JFan speed levels adjustmentServiceABB LV Installation Materials Co., Ltd.Beijing No. 17 Kangding Street, Beijing Economic-Technological Development Area 100176, P.R.China/knx Tel: +86 400-820-9696中文PEONIA 系列智能控制面板警告直接或间接接触导电零件时，可能有触电危险。

12Releasedate:216-12-512:11Dateofissue:217-1-216325_eng.xml 1L+L-23R e l e a s e d a t e : 2016-12-05 12:11D a t e o f i s s u e : 2017-01-02106325_e n g .x m lInstructionManual electrical apparatus for hazardous areas Device category 1Gfor use in hazardous areas with gas, vapour and mist EC-T ype Examination CertificateCE marking ATEX marking ¬ II 1G Ex ia IIC T6…T1 G aThe Ex-related marking can also be printed on the enclosed label.Standards EN 60079-0:2012+A11:2013 EN 60079-11:2012 Ignition protection "Intrinsic safety"Use is restricted to the following stated conditions Appropriate typeNCN50-FP-N0..Effective internal inductivity C i≤ 220 nF ; a cable length of 10 m is considered.Effective internal inductance L i ≤ 360 µH ; a cable length of 10 m is considered.G eneralThe apparatus has to be operated according to the appropriate data in the data sheet and in this instruction manual. The EU-type examination certificate has to beobserved. The special conditions must be adhered to! Directive 94/9/EC and there-fore the EC-type-examination certificates generally apply only to the use of electrical apparatus under atmospheric conditions. The device has been checked for suitabil-ity for use at ambient temperatures of &gt;60°C by the named certification authority. The surface temperature of the device remains within the required limits. If the equip-ment is not used under atmospheric conditions, a reduction of the permissible mini-mum ignition energies may have to be taken into consideration.Ambient temperatureDetails of the correlation between the type of circuit connected, the maximum per-missible ambient temperature, the temperature class, and the effective internal reac-tance values can be found on the EC-type examination certificate. Note: Use the temperature table for category 1 The 20 % reduction in accordance with EN 1127-1 has already been applied to the temperature table for category 1.Installation, commissioningLaws and/or regulations and standards governing the use or intended usage goal must be observed. The intrinsic safety is only assured in connection with an appro-priate related apparatus and according to the proof of intrinsic safety. The associated apparatus must satisfy the requirements of category ia.Due to the possible danger of ignition, which can arise due to faults and/or transient currents in the equipotential bonding system, galvanic isolation of the power supply and signal circuit is preferable. Associated apparatus without electrical isolation must only be used if the appropriate requirements of IEC 60079-14 are met. If the Ex-related marking is printed only on the supplied label, then this must be attached in the immediate vicinity of the sensor. The sticking surface for the label must be clean and free from grease. The attached label must be legible and indelible, including in the event of possible chemical corrosion. After opening the housing, you should check that the seal is in the correct position and is clean and intact before closing the housing again.Maintenance No changes can be made to apparatus, which are operated in hazardous areas.Repairs to these apparatus are not possible.Special conditionsThe connecting parts of the sensor must be set up in such a way that degree of pro-tection IP20, in accordance with lEC 60529, is achieved as a minimum.Protection from mechanical dangerWhen using the device in a temperature range of -60 °C to -20 °C, protect the sensor against the effects of impact by installing an additional enclosure. The information regarding the minimum ambient temperature for the sensor as provided in the datasheet must also be observed.Electrostatic chargeNon-permissible electrostatic charges should be avoided on the plastic housing parts. Information on electrostatic hazards can be found in the technical specification IEC/TS 60079-32-1. Avoid electrostatic charges that can cause electrostatic dis-charge when installing or operating the device.4Releasedate:216-12-512:11Dateofissue:217-1-216325_eng.xmlInstruction Manual electrical apparatus for hazardous areasDevice category 2G for use in hazardous areas with gas, vapour and mistEC-T ype Examination CertificateCE markingATEX marking ¬ II 1G Ex ia IIC T6…T1 G aThe Ex-related marking can also be printed on the enclosed label.Standards EN60079-0:2012+A11:2013,EN60079-11:2012Ignition protection "Intrinsic safety"Use is restricted to the following stated conditionsAppropriate type NCN50-FP-N0..Effective internal inductivity C i≤ 220 nF ; a cable length of 10 m is considered.Effective internal inductance L i≤ 360 µH ; a cable length of 10 m is considered.G eneral The apparatus has to be operated according to the appropriate data in the data sheetand in this instruction manual. The EU-type examination certificate has to beobserved. The special conditions must be adhered to! Directive 94/9/EC and there-fore the EC-type-examination certificates generally apply only to the use of electricalapparatus under atmospheric conditions. The device has been checked for suitabil-ity for use at ambient temperatures of &gt;60°C by the named certification authority.The surface temperature of the device remains within the required limits. If the equip-ment is not used under atmospheric conditions, a reduction of the permissible mini-mum ignition energies may have to be taken into consideration.Maximum permissible ambient temperature T amb Details of the correlation between the type of circuit connected, the maximum per-missible ambient temperature, the temperature class, and the effective internal reac-tance values can be found on the EC-type examination certificate.Installation, commissioning Laws and/or regulations and standards governing the use or intended usage goalmust be observed. The intrinsic safety is only assured in connection with an appro-priate related apparatus and according to the proof of intrinsic safety. If the Ex-relatedmarking is printed only on the supplied label, then this must be attached in the imme-diate vicinity of the sensor. The sticking surface for the label must be clean and freefrom grease. The attached label must be legible and indelible, including in the eventof possible chemical corrosion. After opening the housing, you should check that theseal is in the correct position and is clean and intact before closing the housingagain.Maintenance No changes can be made to apparatus, which are operated in hazardous areas.Repairs to these apparatus are not possible.Special conditions The connecting parts of the sensor must be set up in such a way that degree of pro-tection IP20, in accordance with lEC 60529, is achieved as a minimum.Protection from mechanical danger When using the device in a temperature range of -60 °C to -20 °C, protect the sensoragainst the effects of impact by installing an additional enclosure. The informationregarding the minimum ambient temperature for the sensor as provided in thedatasheet must also be observed.Electrostatic charge Additional requirements for gas group IIC. Avoid electrostatic charges that can causeelectrostatic discharge when installing or operating the device. Information on elec-trostatic hazards can be found in the technical specification IEC/TS60079-32-1.5R e l e a s e d a t e : 2016-12-05 12:11D a t e o f i s s u e : 2017-01-02106325_e n g .x m lInstructionManual electrical apparatus for hazardous areas Device category 1Dfor use in hazardous areas with combustible dust EC-T ype Examination CertificateCE marking ATEX marking ¬ II 1D Ex ia IIIC T135°C DaThe Ex-related marking can also be printed on the enclosed label.Standards EN 60079-0:2012+A11:2013 EN 60079-11:2012Ignition protection "Intrinsic safety" Use is restricted to the following stated condi-tionsAppropriate typeNCN50-FP-N0..Effective internal inductivity C i≤ 220 nF ; a cable length of 10 m is considered.Effective internal inductance L i ≤ 360 µH ; a cable length of 10 m is considered.G eneralThe apparatus has to be operated according to the appropriate data in the data sheet and in this instruction manual. The EU-type examination certificate has to beobserved. The special conditions must be adhered to! The ATEX directive and there-fore the EU-type examination certificates are in general only applicable to the use of electrical apparatus operating at atmospheric conditions.The use in ambient temperatures of > 60 °C was tested with regard to hot surfaces by the mentioned certification authority.If the equipment is not used under atmospheric conditions, a reduction of the permis-sible minimum ignition energies may have to be taken into consideration.Permissible ambient temperature rangeDetails of the correlation between the type of circuit connected, the maximum per-missible ambient temperature, the surface temperature, and the effective internal reactance values can be found on the EC-type-examination certificate. The maxi-mum permissible ambient temperature of the data sheet must be noted, in addition, the lower of the two values must be maintained.Installation, commissioningLaws and/or regulations and standards governing the use or intended usage goal must be observed. The intrinsic safety is only assured in connection with an appro-priate related apparatus and according to the proof of intrinsic safety. If the Ex-related marking is printed only on the supplied label, then this must be attached in the imme-diate vicinity of the sensor. The sticking surface for the label must be clean and free from grease. The attached label must be legible and indelible, including in the event of possible chemical corrosion. After opening the housing, you should check that the seal is in the correct position and is clean and intact before closing the housing again.MaintenanceNo changes can be made to apparatus, which are operated in hazardous areas.Repairs to these apparatus are not possible. After opening the housing, you should check that the seal is in the correct position and is clean and intact before closing the housing again.Special conditionsThe connecting parts of the sensor must be set up in such a way that degree of pro-tection IP20, in accordance with lEC 60529, is achieved as a minimum.Protection from mechanical dangerWhen using the device in a temperature range of -60 °C to -20 °C, protect the sensor against the effects of impact by installing an additional enclosure. The information regarding the minimum ambient temperature for the sensor as provided in the datasheet must also be observed.Electrostatic chargeAvoid electrostatic charges that can cause electrostatic discharge when installing or operating the device. Information on electrostatic hazards can be found in the techni-cal specification IEC/TS 60079-32-1. Do not attach the nameplate provided in areas where electrostatic charge can build up.。

全集成式传感器常规应用指导手册修订履历：Revision Change Page Author Date1.0 Initial draft Deng 2018.101.1 优化绝缘设计描述黄琳2020.061.2 新增过流保护功能Deng 2021.071.3 添加安全认证描述Deng 2022.08目录一、芯片式传感器常规问题 (2)1.1.1 芯片能够同时检测交流和直流电流吗 (2)1.1.2 外围电容的作用及选择 (3)1.1.3 有什么办法可以调整芯片的灵敏度吗 (3)1.1.4 REF功能不使用是悬空还是接地 (3)1.1.5 如果我试图用传感器IC的输出驱动超过规定的10nF最大电容会发生什么 (3)1.1.6 如果我试图用传感器IC的输出驱动超过规定的最小电阻会发生什么 (2)1.1.7 芯片适用的测量交流电频率范围 (3)1.1.8 兴工微电流传感器有什么安全认证 (3)1.1.9 如何降低焊接机械应力带来的影响 (3)1.2.0 应用时极限参数超出规范会有什么影响 (3)1.2.1响应时间与Cout容值的关系 (3)1.2.2 RC滤波对噪声的影响 (3)1.2.3采用程序清零的因素 (3)1.2.4各型号的输出电压线性范围和饱和范围 (3)二、过流保护功能 (1)2.1.1过流管脚功能不使用如何处理 (2)2.2.2OCST功能如何使用 (3)2.2.3FLAG管脚输出特性 (3)2.2.4如何保障FLAG管脚信号响应时间<2uS (3)三、传感器设计准则 (1)3.1.1 概述 (2)3.1.2 热效应带来的影响 (3)3.1.3 载流迹线对IC的影响 (3)3.1.4 载流迹线与芯片距离变化带来的误差和危害 (3)3.1.5 绝缘设计 (3)四、电流能力和耐受时间关系 (4)4.1.1 概述 (5)4.1.2 电流与温升关系 (5)4.1.3 PCB不同面积下电流造成的温升对比 (5)4.1.4 由于短路冲击电流或其他瞬态条件造成的框体熔断 (5)4.1.5 超温或熔断的危害 (5)一、芯片式传感器常规问题1.1.1 芯片能够同时检测交流和直流电流吗对。

© Freescale Semiconductor, Inc., 2005. All rights reserved.On-Chip Signal Conditioned,Temperature Compensatedand CalibratedThe Freescale MPXHZ6250A series sensor integrates on-chip, bipolar opamp circuitry and thin film resistor networks to provide a high output signal andtemperature compensation. The small form factor and high reliability of on-chipintegration make the Freescale sensor a logical and economical choice forautomotive system designers.The MPXHZ6250A series piezoresistive transducer is a state-of-the-art,monolithic, signal conditioned, silicon pressure sensor. This sensor combinesadvanced micromachining techniques, thin film metallization, and bipolarsemiconductor processing to provide an accurate, high level analog output signalthat is proportional to applied pressure.Figure 1 shows a block diagram of the internal circuitry integrated on apressure sensor chip.Features•Improved Accuracy at High Temperature •Available in Small and Super Small Outline Packages •1.5% Maximum Error over 0° to 85°C •Ideally suited for Microprocessor or Microcontroller-Based Systems •Temperature Compensated from –40° to +125°C •Durable Thermoplastic (PPS) Surface Mount Package Typical Applications•Industrial Controls •Engine Control/Liquified Petroleum Gas (LPG)ORDERING INFORMATIONDeviceTypeOptions Case No.MPX Series Order No.Packing Options Device Marking PortedElement Absolute, Axial Port1317A MPXHZ6250AC6T1Tape & Reel MPXHZ6250A INTEGRATED PRESSURE SENSOR 20 to 250 kPa (3.0 to 36 psi)0.3 to 4.9 V OUTPUT PIN NUMBERS (1)1.Pins 1, 5, 6, 7, and 8 are internal device connections. Do not connect to external circuitry or ground. Pin 1 is noted by the notch in the lead.1N/C 5N/C 2V S 6N/C 3GND 7N/C 4V OUT 8N/CMPXHZ6250ASensorsFigure 1. Fully Integrated Pressure Sensor SchematicTable 1. Maximum Ratings (1)1. Exposure beyond the specified limits may cause permanent damage or degradation to the device. RatingSymbol Value Unit Maximum PressureP MAX 1000kPa Storage Temperature T STG –40 to +125°C Operating TemperatureT A –40 to +125°C Output Source Current @ Full Scale Output (2)2. Maximum Output Current is controlled by effective impedance from V out to GND or V out to V S in the application circuit.I o +0.5mAdc Output Sink Current @ Minimum Pressure Offset 2I o –-0.5mAdcGND Pins 1, 5, 6, 7, and 8 are NO CONNECTSfor small outline package devices.MPXHZ6250ASensors202501.Device is ratiometric within this specified excitation range.4.755.0 5.256.010@ V S = 5.0 Volts (2)2.Offset (V off ) is defined as the output voltage at the minimum rated pressure.off 0.1310.20.269Full Scale Output(0 to 85°C)@ V S = 5.0 Volts (3)3.Full Scale Output (V FSO ) is defined as the output voltage at the maximum or full rated pressure.V FSO 4.731 4.8 4.869Vdc Full Scale Span(0 to 85°C)@ V S = 5.0 Volts (4)4.Full Scale Span (V FSS ) is defined as the algebraic difference between the output voltage at full rated pressure and the output voltage at the minimum rated pressure.V FSS 4.462 4.6 4.738Vdc Accuracy (5)(0 to 85°C)5.Accuracy is the deviation in actual output from nominal output over the entire pressure range and temperature range as a percent of span at 25°C due to all sources of error including the following:•Linearity:Output deviation from a straight line relationship with pressure over the specified pressure range.•Temperature Hysteresis:Output deviation at any temperature within the operating temperature range, after the temperature is cycled toand from the minimum or maximum operating temperature points, with zero differential pressure applied.•Pressure Hysteresis:Output deviation at any pressure within the specified range, when this pressure is cycled to and from theminimum or maximum rated pressure, at 25°C.•TcSpan:Output deviation over the temperature range of 0 to 85°C, relative to 25°C.•TcOffset:Output deviation with minimum rated pressure applied, over the temperature range of 0 to 85°C, relative to 25°C.•Variation from Nominal:The variation from nominal values, for Offset or Full Scale Span, as a percent of V FSS , at 25°C.———±1.5%V FSS SensitivityV/P —20—mV/kPa Response Time (6)6.Response Time is defined as the time for the incremental change in the output to go from 10% to 90% of its final value when subjected to a specified step change in pressure.t R — 1.0—ms Warm-Up Time (7)7.Warm-up Time is defined as the time required for the product to meet the specified output voltage after the Pressure has been stabilized.——20—ms Offset Stability (8)8.Offset Stability is the product's output deviation when subjected to 1000 hours of Pulsed Pressure, Temperature Cycling with Bias Test.——±0.25—%V FSSMPXHZ6250ASensors 23Figure 2. Typical Application Circuit(Output Source Current Operation)Figure 3. Output versus Absolute Pressure V S Pin 2GND Pin 3V OUT Pin 4MPXHZ6250A To ADC100 nF 51 K 47 pF O u t p u t (V o l t s )Pressure (Reference to Sealed Vacuum) in kPa 203143546677891001121231351461581691811922042152272384.504.05.01.01.52.02.53.03.50.5250Transfer Function:V out = V s *(0.0040*P-0.040) ± Error V S = 5.0 Vdc Temperature = 0 to 85°CMIN MAX TYPMPXHZ6250ASensorsSURFACE MOUNTING INFORMATIONMinimum Recommended Footprint for Super Small Outline PackagesSurface mount board layout is a critical portion of the totaldesign. The footprint for the semiconductor package must bethe correct size to ensure proper solder connection interfacebetween the board and the package. With the correct padgeometry, the packages will self-align when subjected to asolder reflow process. It is always recommended to fabricateboards with a solder mask layer to avoid bridging and/orshorting between solder pads, especially on tight tolerancesand/or tight layouts.Figure 4. SSOP Footprint (Case 1317A)Temp Multiplier -4030 to 851125 1.75Temperature in °C4.03.02.00.01.0-40-20020406014012010080TemperatureErrorFactor NOTE: The Temperature Multiplier is a linear response from 0°C to -40°C and from 85°C to 125°C.Pressure Error (Max)Pressure Error Band20 to 250 (kPa)±3.45 (kPa)MPXHZ6250APressure (in kPa)Error Limits for Pressure Break Points 3.02.01.0-1.0-2.0-4.00.04.0-3.020P r e s s u r e E r r o r (k Pa )601001401802202603000.027 TYP 8X0.690.053 TYP 8X1.35inch mm0.3879.830.1503.810.0501.27TYPMPXHZ6250ASensorsISSUE CSUPER SMALL OUTLINE PACKAGEMPXHZ6250ASensorsISSUE CSUPER SMALL OUTLINE PACKAGEHow to Reach Us:Home Page:E-mail:*********************USA/Europe or Locations Not Listed: Freescale SemiconductorTechnical Information Center, CH370 1300 N. Alma School Road Chandler, Arizona 85224+1-800-521-6274 or +1-480-768-2130 *********************Europe, Middle East, and Africa:Freescale Halbleiter Deutschland GmbHTechnical Information CenterSchatzbogen 781829 Muenchen, Germany+44 1296 380 456 (English)+46 8 52200080 (English)+49 89 92103 559 (German)+33 1 69 35 48 48 (French)*********************Japan:Freescale Semiconductor Japan Ltd.HeadquartersARCO Tower 15F1-8-1, Shimo-Meguro, Meguro-ku,Tokyo 153-0064Japan0120 191014 or +81 3 5437 9125***************************Asia/Pacific:Freescale Semiconductor Hong Kong Ltd.Technical Information Center2 Dai King StreetTai Po Industrial EstateTai Po, N.T., Hong Kong+800 2666 8080**************************For Literature Requests Only:Freescale Semiconductor Literature Distribution Center P.O. Box 5405Denver, Colorado 802171-800-441-2447 or 303-675-2140Fax: 303-675-2150*********************************************MPXHZ6250ARev. 0Information in this document is provided solely to enable system and software implementers to use Freescale Semiconductor products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits or integrated circuits based on the information in this document.Freescale Semiconductor reserves the right to make changes without further notice to any products herein. Freescale Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters that may be provided in Freescale Semiconductor data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”, must be validated for each customer application by customer’s technical experts. Freescale Semiconductor does not convey any license under its patent rights nor the rights of others. Freescale Semiconductor products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Freescale Semiconductor product could create a situation where personal injury or death may occur. Should Buyer purchase or use Freescale Semiconductor products for any such unintended or unauthorized application, Buyer shall indemnify and hold Freescale Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Freescale Semiconductor was negligent regarding the design or manufacture of the part. Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners.© Freescale Semiconductor, Inc. 2005. All rights reserved.。

GeneralThe following questionnaires are used to select sensors according to the client's requirements.The characteristics shown in the catalogue are given with respect to a defined environment (worst case conditions).The technical requirements will not always reach these extreme limits, and it is possible, following confirmation by us, to propose higher maximum electrical or thermal values to those published, thanks to a knowledge and detailed analysis of the sensor operating environment.A technical relationship between the client and ABB will allow the proposal of the best selection of sensors, equally from the viewpoint of performance and economy.Two principal areas are considered in the selection of a sensor:–the electrical aspect–the thermal aspectThe sensor performance is based on a combination of electrical and thermal conditions; any values other than those indicated in this catalogue cannot be guaranteed unless validated by us. The information below is only valid for sensors using closed loop Hall effect technology.Contact your local supplier for other technologies.Profile missionDue to the design of converters with integrate more power with less volume, sensors are very constraint; leading to reduce their life time. As a matter of fact, even though the application main conditions are well within the sensors characteristics, these conditions have an impact on the sensor life time.The main general characteristics that involves the sensors life time are the following:–the ambient temperature above 40 °C. It is usually said that every additional 10 °C, the life time is reduced by a factor of 2. Of course, this value is a theoretical value and has to be defined in line with the concerned project.–the ambient temperature variations also impact the sensor life time. Even small variations (like 10 °C) can change the life time of the sensor especially on the electronic part.–the way the sensors are used also impact its duration (numbers of ON/OFF per day, average current or voltage value, powersupply value, load resistor value, vibrations levels…)The above general impacting conditions are well defined in standards like IEC 62380, UTE C 80-810 and must be consider during any new converter design.ABB can provide theoretical reliability calculation based on specific profile mission of your projects.Electrical characteristicsThe electrical characteristics values mentioned in this catalogue are given for a particular sensor operating point. These values may vary, according to the specific technical requirement, in the following way:–The primary thermal current (voltage) (I PN or U PN) may be increased if:-t he maximum operating temperature is lower than thevalue shown in the technical data sheet-the sensor supply voltage (V A) is reduced-the load resistance value (R M) is increased–The maximum current (voltage) measurable by the sensor may be increased if:-the maximum operating temperature is lower than thevalue shown in the technical data sheet-the sensor supply voltage (V A) is increased-the secondary winding resistance value (R S) is reduced(e.g. by using a lower transformation ratio)-the load resistance value (R M) is reducedThermal characteristicsThe operating temperature values mentioned in this catalogue are given for a particular sensor operating point. These values may vary, according to the specific technical requirement, in the following way:–The maximum operating temperature may be increased if: -the primary thermal current (voltage) (I PN or U PN) is reduced -the sensor supply voltage (V A) is reduced-the load resistance value (R M) is increasedPS: The minimum operating temperature cannot be lower than that shown in the technical data sheet as this is fixed by the lower temperature limit of the components used in the sensor.74S21Application1. Application :–Variable speed drive ................................................................ –UPS ....................................................................................... –Wind generator ....................................................................... –Active harmonic filter ............................................................... –Welding machines ................................................................... –Solar ...................................................................................... –Other (description) ......................................................................2. Quantity per year: ...........................................................................Mechanical characteristics1. Sensor fixing:–By soldering to the PCB .......................................................... –By the enclosure ..................................................................... –By the primary conductor ........................................................ 2. Primary conductor:–Cable diameter ................................................................... (mm) –Cable connection size ......................................................... (mm) –Bar size .............................................................................. (mm)3. Secondary connection:–By connector .......................................................................... –By cable without connector ..................................................... –Other ......................................................................................Sensor environmental conditions1. Minimum operating temperature ................................................ (°C)2. Maximum operating temperature ............................................... (°C)3. Presence of strong electromagnetic fields ....................................4. Max. continuous primary conductor voltage ................................ (V)5. Main reference standards ................................................................Electrical characteristics1. Nominal current (I PN ) ......................................................... (A r.m.s.)2. Current type (if possible, show current profile on graph):–Direct ..................................................................................... –Alternating .............................................................................. 3. Bandwidth to be measured ...................................................... (Hz)4. Current measuring range:–Minimum current .................................................................... (A) –Maximum current ................................................................... (A) –Duration (of max. current) .................................................... (sec) –Repetition (of max. current) ......................................................... –Measuring voltage (on R M ) at max current .............................. (V)5. Overload current (not measurable):–Not measurable overload current ........................................... (A) –Duration.............................................................................. (sec) –Repetition ...................................................................................6. Sensor supply voltage:–Bipolar supply voltage .......................................................... (±V) –Unipolar supply voltage .......................................... (0 +V or 0 -V)7. Output current–Secondary current at nominal current I PN ............................. (mA) 8. Current output (NCS range only)–Secondary current at maximum current I PMAX ....................... (mA)9. Voltage output–Secondary voltage at nominal current I PN ............................... (V)10. Voltage output (NCS range only)–Secondary voltage at maximum current I PMAX (V)Company:Address:Tel:Name:Fax:Email:Other requirements (description)74S 0201Company:Address:Tel:Name:Fax:Email:Other requirements (description)Application1. Project name ...................................................................................2. Application:Rolling stock:–Power converter ..................................................................... –Auxiliary converter ................................................................... –Other ......................................................................................Short or long distance train:–Power converter ..................................................................... –Auxiliary converter ...................................................................Metro or tramway:–Power converter ..................................................................... –Auxiliary converter ................................................................... Fixed installation (e.g. substation)..................................................... 3. Quantity per year: ............................................................................4. Total quantity for the project.............................................................Mechanical characteristics1. Sensor fixing:–By the enclosure ..................................................................... –By the primary conductor ........................................................ 2. Primary conductor:–Cable diameter ................................................................... (mm) –Bar size .............................................................................. (mm) 3. Secondary connection:–Screw or Faston...................................................................... –By connector .......................................................................... –By shielded cable .................................................................... –Other ...................................................................................... Electrical characteristics1. Nominal current (I PN ) .......................................................... (A r.m.s.)2. C urrent type (if possible, show current profile on graph):–Direct ..................................................................................... –Alternating .............................................................................. 3. Bandwidth to be measured ....................................................... (Hz)4. Current measuring range:–Minimum current .................................................................... (A) –Maximum current ................................................................... (A) –Duration (of max. current) .................................................... (sec) –Repetition (of max. current) ......................................................... –Measuring voltage (on R M ) at max current .............................. (V)5. Overload current (not measurable):–Not measurable overload current ............................................(A) –Duration.............................................................................. (sec) –Repetition ...................................................................................6. Sensor supply voltage:–Bipolar supply voltage .......................................................... (±V) –Unipolar supply voltage .......................................... (0 +V or 0 -V)7. Output current–Secondary current at nominal current I PN ............................. (mA) 8. Current output (NCS125 & NCS165 only for fixed installations)–Secondary current at maximum current I PMAX ....................... (mA)9. Voltage output (NCS125 & NCS165 only for fixed installations)–Secondary voltage at nominal current I PN ............................... (V)10. Voltage output (NCS125 & NCS165 only for fixed installations)–Secondary voltage at maximum current I PMAX (V)Sensor environmental conditions1. Minimum operating temperature ................................................ (°C)2. Maximum operating temperature ............................................... (°C)3. Average nominal operating temperature ......................................(°C)4. Maximum continuous primary conductor voltage ..........................(V)5. Main reference standards ................................................................74S 0201Company:Address:Tel:Name:Fax:Email:Other requirements (description)Application1. Project name ...................................................................................2. Application:Short or long distance train:–Power converter ..................................................................... –Auxiliary converter ...................................................................Metro or tramway:–Power converter ..................................................................... –Auxiliary converter ...................................................................Fixed installation (e.g. substation) ................................................ 3. Quantity per year: ............................................................................4. Total quantity for the project.............................................................Mechanical characteristics1. Primary connection:–By screw ................................................................................ –Other ...................................................................................... 2. Secondary connection:–Screw or Faston...................................................................... –By connector .......................................................................... –Other ...................................................................................... Electrical characteristics1. Nominal voltage (U PN ) ........................................................ (V r.m.s.)2. Voltage type (if possible, show voltage profile on graph):–Direct ..................................................................................... –Alternating .............................................................................. 3. Bandwidth to be measured ...................................................... (Hz)4. Voltage measuring range:–Minimum voltage .................................................................... (V) –Maximum voltage ................................................................... (V) –Duration (at max. voltage) .................................................... (sec) –Repetition (at max. voltage) ......................................................... –Measuring voltage (on R M ) at max voltage ............................... (V)5. Overload voltage (not measurable):–Not measurable overload voltage ............................................ (V) –Duration.............................................................................. (sec) –Repetition ................................................................................... –Category (from OV1 to OV3) ........................................................6. Sensor supply voltage:–Bipolar supply voltage .......................................................... (±V) –Unipolar supply voltage .......................................... (0 +V or 0 -V)7. Output current–Secondary current at nominal voltage U PN ............................ (mA)Sensor environmental conditions1. Minimum operating temperature ................................................ (°C)2. Maximum operating temperature ............................................... (°C)3. Average nominal operating temperature .....................................(°C)4. Main reference standards ................................................................74S 0201Company:Address:Tel:Name:Fax:Email:Other requirements (description)Application1. Project name ...................................................................................2. Application:Short or long distance train:–Power converter ..................................................................... –Auxiliary converter ...................................................................Metro or tramway:–Power converter ..................................................................... –Auxiliary converter ...................................................................Fixed equipment (e.g. substation) ................................................ 3. Quantity per year: ...........................................................................4. Total quantity for the project.............................................................Electrical characteristics1. Nominal voltage (U PN ) ............................................................ (V DC)2. Maximum voltage long duration: 5 min (U MAX2) ........................ (V DC)3. Maximum voltage overload: 20 ms (U MAX3) .............................. (V DC)4. Minimum voltage to be detected . (V)Sensor environmental conditions1. Minimum operating temperature ................................................ (°C)2. Maximum operating temperature ............................................... (°C)3. Average nominal operating temperature ..................................... (°C)4. Pollution degree ..............................................................................5. Over voltage category (from OV1 to OV3) .........................................6. Maximum ambient light level ......................................................(lux)7. Main reference standards ................................................................74S 0201。

L e v N e t R F ™ 902 M H z P I R S u r f a c e M o u n t O c c u p a n c y S e n s o rBASIC OPERATIONThe LevNet RF™ 902 MHz PIR Surface Mount Occupancy Sensor (WSC12) has built-in solar cells that draw on available ambient light to power themselves and can operate for up to 80 hours in total darkness. Batteries are not required.For improved detection, the sensor uses an enhanced PIR element located directly behind a unique multi-zone optical lens. This exclusive Fresnel lens establishes twice as many zones of detection as traditional sensors.The self-powered wireless sensor designalso overcomes the placement and coverage challenges of traditional sensors. Self-powered wireless sensors enable flexible placement, allowing sensors to be mounted where needed without the complexity of moving or installing new wiring.APPLICATIONS • Retrofits• New construction • Restrooms• Conference rooms • Classrooms • Private offices • Executive offices • Daycare facilities • Restaurant• Houses of worship • Shop/Garage • Gym• RestaurantLevNet RF™ 902 MHz PIRSurface Mount Occupancy SensorFor use with LevNet 902 MHz RF ProductsFEATURES• Zero Power Consumption — solar cells provide the energy to keep the device on and sensor technology turns the lights off, eliminating additional expenses to the end user’s energy bill• Zero Wiring Required — no wire limitations enable the installer to place the sensor in the optimal location of any application to capture minor motion and enhance performance• Self-Powered, Self-Charging — angled solar cells are optimal for light collection, enabling the sensor to capture additional ambient(natural and artificial) light over flat solar cells 9FC vs. 6-7FC (100 LUX vs. 64-75 LUX)• Rapid Charge Time to Operation — self-powered technology enables the sensor to be operational after a minimum charge time of 1 minute• True Wireless — sensors are self-powered and communicate with all LevNet RF and EnOcean ® Receivers via a 902 MHz radio frequency• No Additional Wiring — self-powered wireless technology eliminates the need to pull additional wire, making installation quick and easy and increasing labor savings with little to no impact to business during conversion• Up to 80 Hours of Stored Power — solar cells provide up to 80 hours of power to the sensor when no ambient light is available (for extended “OFF” time, an optional battery can be inserted)• Advanced Field-of-View — superior detection for parallel and perpendicular motion;innovative technology detects motion moving directly towards the sensor; 360° rotation to fine-tune the location of solar cells and field-of-view• Improved Aesthetics — blends seamlessly with ceiling décor and architecture• Additional Energy Savings — wirelesstechnology supports manual override optionswith no additional wiringLeviton Manufacturing Co., Inc. Global Headquarters201 North Service Road, Melville, NY 11747-3138 tech line 800-824-3005 fax 800-832-9538 ©2015 Leviton Manufacturing Co., Inc. All rights reserved. Subject to change without notice.PRODUCT DATAG-9229A/L15-tb REV DEC 2015902 FIELD-OF-VIEW (IN FEET)DIMENSIONSContact Leviton for a complete list of LevNet RF 902 MHz self-powered wireless solutions. The line includes wall switch receivers, line-voltage relay receivers and more.Leviton Manufacturing Co., Inc. Global Headquarters201 North Service Road, Melville, NY 11747-3138 tel 800-323-8920 fax 800-832-9538 tech line (8:30AM-7:00PM ET Mon-Fri) 800-824-3005Leviton Manufacturing Co., Inc. Energy Management, Controls and Automation20497 SW Teton Avenue, Tualatin, OR 97062 tel 800-736-6682 fax 503-404-5594 tech line (6:00AM-4:00PM PT Mon-Fri) 800-959-6004Visit our Website at: /levnetrf©2015 Leviton Manufacturing Co., Inc. All rights reserved. Subject to change without notice.。